Dark Ring of a Microdisplay and Its Driving Method

1. A method for driving a dark ring of a microdisplay during a frame period, said microdisplay including a display area having a plurality of pixels for displaying an image, comprising: providing a dark ring surrounding the plurality of pixels of the display area, said dark ring including a dark ring up metal and a dark ring down metal, said dark ring up metal and said dark ring down metal being electrically isolated from each other; controlling said dark ring up metal to show an all-black image during a frame period firstly; controlling the pixels of the display area to show the image during the frame period secondly; and controlling said dark ring down metal to show an all-black image during the frame period lastly; wherein the polarity for each of said dark ring up metal and said dark ring down metal is adjusted in accordance with the polarity of adjoining pixels within the microdisplay and the scan direction of gate drivers to coincide with that for adjoining pixels within the display area; wherein the polarity of the dark ring up metal changes from positive to negative synchronously with a topmost scan line within the microdisplay to coincide with the polarity inversion for the adjoining pixels on the topmost scan line within the display area; wherein the polarity of the dark ring down metal changes from positive to negative synchronously with a bottommost scan line within the microdisplay to coincide with the polarity inversion for the adjoining pixels on the bottommost scan line within the display area; and wherein the polarity of the dark ring down metal does not change from positive to negative synchronously with the change from positive to negative of the polarity of the dark ring up metal.

2. The method according to claim 1 , wherein said microdisplay is a liquid-crystal-on-silicon (LCOS) display.

3. The method according to claim 1 , wherein each of said dark ring up metal and said dark ring down metal is controlled according to the polarity of the adjoining pixels within the display area and the scan direction of gate drivers for the microdisplay.

4. The method according to claim 1 , wherein said dark ring up metal is disposed on a top periphery of the display area, and said dark ring down metal is disposed on a lower periphery of the display area.

5. The method according to claim 4 , wherein said dark ring up metal has a reverse polarity inversion with respect to said dark ring down metal.

6. The method according to claim 1 , wherein said dark ring further includes at least a side portion disposed on a side periphery of the display area.

7. The method according to claim 6 , wherein said side portion has a same polarity inversion as the adjoining pixels within the display area.

8. A microdisplay, comprising: a display area having a plurality of pixels for displaying an image during a frame period; a dark ring surrounding the plurality of pixels of the display area, said dark ring including a dark ring up metal and a dark ring down metal, each of said dark ring up metal and dark ring down metal being electrically isolated from each other; and a logic circuit for controlling said dark ring up metal to show an all-black image during a frame period firstly, then controlling the pixels of the display area to show the image during the frame period secondly, and then controlling said dark ring down metal to show an all-black image during the frame period lastly; wherein the polarity for each of said dark ring up metal and said dark ring down metal are adjusted in accordance with the polarity of adjoining pixels within the microdisplay and the scan direction of gate drivers to coincide with that for adjoining pixels within the display area; wherein the polarity of the dark ring up metal changes from positive to negative synchronously with a topmost scan line within the microdisplay to coincide with the polarity inversion for the adjoining pixels on the topmost scan line within the display area; wherein the polarity of the dark ring down metal changes from positive to negative synchronously with a bottommost scan line within the microdisplay to coincide with the polarity inversion for the adjoining pixels on the bottommost scan line within the display area; and wherein the polanty of the dark ring down metal does not change from positive to negative synchronously with the change from positive to negative of the polarity of the dark ring up metal.

9. The microdisplay according to claim 8 , wherein said microdisplay is a liquid-crystal-on-silicon (LCOS) display.

10. The microdisplay according to claim 8 , wherein said logic circuit controls each of said dark ring up metal and said dark ring down metal according to a polarity of the adjoining pixels within the display area and a scan direction of gate drivers for the microdisplay.

11. The microdisplay according to claim 10 , wherein said dark ring further includes at least a side portion disposed on a side periphery of the display area.

12. The microdisplay according to claim 11 , wherein said logic circuit controls said side portion such that said side portion has a same polarity inversion as the adjoining pixels within the display area.

13. The microdisplay according to claim 11 , wherein said side portion comprises redundant pixels formed in side peripherals of the display area.

14. The microdisplay according to claim 8 , wherein said dark ring up metal is disposed on a top periphery of the display area, and said dark ring down metal is disposed on a lower periphery of the display area.

15. The microdisplay according to claim 8 , wherein said logic circuit controls said dark ring up metal and said dark ring down metal such that said dark ring up metal has a reverse polarity inversion with respect to said dark ring down metal.

16. A dark ring of a microdisplay, comprising: a plurality of portions, formed on peripheral of a display area of the microdisplay, and comprising: a dark ring up metal portion disposed on a top periphery of the display area; and a dark ring down metal portion disposed on a lower periphery of the display area; wherein said dark ring up metal portion and said dark ring down metal portion are formed on a top surface of the microdisplay; wherein each of said dark ring up metal portion and said dark ring down metal portion are electrically isolated from each other, and the polarity for each of said dark ring up metal portion and said dark ring down metal portion is adjusted in accordance with the polarity of adjoining pixels within the microdisplay and the scan direction of gate drivers to coincide with that for adjoining pixels within the microdisplay; and wherein the polarity of the dark ring up metal changes from positive to negative synchronously with a topmost scan line within the microdisplay to coincide with the polarity inversion for the adjoining pixels on the topmost scan line within the display area; wherein the polarity of the dark ring down metal changes from positive to negative synchronously with a bottommost scan line within the microdisplay to coincide with the polarity inversion for the adjoining pixels on the bottommost scan line within the display area; and wherein the polarity of the dark ring down metal does not change from positive to negative synchronously with the change from positive to negative of the polarity of the dark ring up metal.

17. The dark ring according to claim 16 , wherein said microdisplay is a liquid-crystal-on-silicon (LCOS) display.

18. The dark ring according to claim 16 , wherein said portions further includes at least a side portion disposed on a side periphery of the display area, wherein said side portion comprises redundant pixels formed in side peripherals of the display area.